Shrimp fishing apparatus

ABSTRACT

An apparatus for daylight shrimp fishing is disclosed. The apparatus includes a plurality of Otter trawls each having an electrode array and a pulse circuit. Each pulse circuit includes a capacitor which is discharged by a reversal of current to the capacitor which fires an SCR. A control unit located on the boat effects the discharging of the respective capacitors in a predetermined sequence to equalize the load on an alternating current generator. The electrode array has a plurality of electrodes which trail behind a bus extending between the trawl doors at a distance above the bottom. The electrodes are weighted to slide along the bottom and have an insulating material disposed above the conductor so that the electric current pulses are directed into the bottom rather than being dissipated upwardly into the water. The design of the bus and the electrode array is such as to insure uniform current density over the array.

United States Patent [191 Newman et al.

[ Dec. 11, 1973 SHRIMP FISHING APPAR'ATUS [76] Inventors: James L. Newman, 1321 Glen Cove,

Richardson, Tex. 75080; Millo Marion Hawthorne, 4824 Overton, Forth Worth, Tex. 76133 [22] Filed: Oct. 3, 1972 [21] Appl. No.: 303,413

Related US. Application Data [63] Continuation of Ser. No. 883,187, Dec. 8, 1969,

abandoned.

52 us. Cl.. 43/9, 43/17.1

[51] Int. Cl A0lk 73/02 [58] Field of Search 43/17 .1, 9; 307/106, 307/107, 108; 328/59, 63, 67

[56] References Cited UNITED STATES PATENTS 2,991,421 7/1961 Volz 43/17.l

3,312,011 4/1967 Wathne et al.. 43/17.l

3,415,001 12/1968 Ott et al 43/l7.l

3,483,649 12/1969 Klima ct al. 43/l7.l

3,491,474 l/l970 Metcalf, Jr 43/9 Primary ExaminerWarner H. Camp Att0rneyD. Carl Richards et al.

[57] ABSTRACT An apparatus for daylight shrimp fishing is disclosed. The apparatus includes a plurality of Otter trawls each having an electrode array and a pulse circuit. Each pulse circuit includes a capacitor which is discharged by a reversal of current to the capacitor which fires an SCR. A control unit located on the boat effects the discharging of the respective capacitors in a predetermined sequence to equalize the load on an alternating current generator. The electrode array has a plurality of electrodes which trail behind a bus extending between the trawl doors at a distance above the bottom. The electrodes are weighted to slide along the bottom and have an insulating material disposed above the conductor so that the electric current pulses are directed into the bottom rather than being dissipated upwardly into the water. The design of the bus and the electrode array is such as to insure uniform current density over the array.

21 Claims, 11 Drawing Figures PAIENTEBUEC 11 ms 3,777,388

sum 1 c; 4 7

INVENTORS'. JAMES L. NEWMAN M. MAR/ON HAWTHORNE ATTORNEYS -ATENTEUD EC 11 mm 3.777.386

INVENTORS JAMES L. NEWMAN F/ 6 M. MAR-ION HAWTHORNE ATTORN EYS SHRIMP FISHING APPARATUS This is a continuation of now abandoned application Ser. No. 883,187, filed Dec. 8, 1969.

This invention relates generally to shrimp trawling apparatus, and more particularly relates to an improved electric shrimp trawl.

Penaeus aztecus and penaeus duorarum shrimp are, by nature, nocturnal creatures. During the day, they burrow into the bottom of the sea and lie dormant. Only during the hours of darkness do they come out into the water to feed where they can be captured by a trawl net. Since shrimp boats normally operate a substantial distance from shore where it is impractical to return after each nights operation, about 50 percent of the total lapsed time of each fishing trip is not productive.

Researchers have discovered that involuntary muscular contractions occur within the body of a shrimp when it is exposed to electrical impulses. When the voltage of the pulses exceed a certain threshold and are at a certain rate, the involuntary contractions are sufficient to cause a shrimp burrowed in the sea bottom to literally hop several inches out of its hiding place into the water so that it can be caught by a net. If the voltage from end to end of the shrimp does not exceed acertain threshold, or if the pulses are too slow or too fast, the shrimp do not hop out of the sea bottom. If the shrimp are oriented transversely of the polarity of the electric field,'the voltage from end to end of the shrimp is inadequate and no contractions result.

Electrical shrimp trawls utilizing this phenomenon have been successfully tested. In one such device, electrodes were arrayed between the trawl doors so as to trail the doors in hyperbolic arcs at spaced intervals in advance of the mouth of the trawl net. In other systems, such as that disclosed in US. Pat. No. 3,312,011, the electrodes were arrayed parallel to the direction of travel of the trawl net with the trailing ends attached to the footrope of the trawl and the leading ends attached to a support cable strung between the bottom edges of the trawl doors. While these systems allow a shrimp trawler to operate around-the clock during the period that it is away from port, a number of problems exist cerned with an improved system for operating one. or

more electric trawls with maximum efficiency. The system also materially reduces'the number of components attached to the trawl, thus reducing the initial cost of the system and the loss in the event a tow line is broken. The invention is also concerned with a more'efficient electrode and electrode array which will operate even over rough bottoms.

The novel features believed characteristic of this invention are set forth in the appended claims. The invention itself, however, as well as other objects and advantages thereof, may best be understood by reference to the following detailed description of illustrated embodiments when read in conjunction with the accompanying drawings, wherein:

FIG. 1 illustrates a shrimp boat towing two Otter trawls and a try net all rigged in accordance with the present invention;

FIG. 2 is a perspective'view of oneofthe Otter trawls of'FIG. l;

FIG. 3 is a partial plan view of the Otter trawl of FIG.

FIG. 4 is a partial sectional view taken on lines 44 of FIG. 3;

FIG. 5 is a schematic diagram illustrating the electrical system of the present invention;

FIG. 6 is a timing diagram which serves to illustrate the operation of the system of FIG. 5;

FIG. 7 is a schematic circuit diagram of the electrode array illustrated in FIGS. 24;

FIG. 8 is a schematic circuit diagram of an alternative electrode array in accordance with the present invention;

FIG. 9 is a side view of one of the electrodes of the array of the trawl net of FIG. 2;

FIG. 10 is a sectional view taken substantially on lines 10-10 of FIG. 9;

FIG. 11 is a bottom view of a portion of another electrode array in accordance with the present invention.

Referring now to the drawings, and in particular to FIG. 1, a shrimp boat 10 is illustrated as towing first and second Otter trawls 12 and 14, and a try net 16. The Otter trawl 14 is identical to the Otter trawl 12 which is illustrated in FIGS. 2-4. The try net 16 is similar to the full-size Otter trawls except that it is substantially smaller. The'trawl 12 includes a pair of Otter doors l8 and 20.which are connected by chains 22 and 24 to the bridle legs 26 and 28 to the tow cable 30. A headrope 32 extends between the upper rear comers of the doors l8 and 20, a footrope 34 extends between the lower rear comers of the door, and the net extends between the headrope 32 and footrope 34 substantially in the configuration illustrated as the net is pulled through the water by the boat.

A pulse circuit is disposed in a watertight container 36 affixed to the rear face of the door 20 and is connected to supply current pulses, as will presently be described, to an electrode array 37 which includes a bus wire 38 affixed to the trailing edges of the doors l8 and 20 at points spaced above the lower edges of the doors so as to be positioned a distance above the bottom as the trawl is pulled through the water. Floats may be attached to the bus 38 if desired to keep the bus at the desired heightabove the bottom. A plurality of electrodes 40 are attached both electrically "and mechanically to the bus 38 and are weighted so as to trail along adjacent the bottom as hereafter described.

Referring now to FIG. 5, alternating current generator 50 is located on the boat 10. The primary winding 52 of a transformer is connected across the generator 50. The secondary winding 54 supplies power to a pulse-shaping circuit 56, which may include a rectifier and a Schmit trigger. The pulse shaper 56 produces a pulse for each positive going half cycle of the generator 50 which are counted by a reset counter 58.

The counter 58 counts a predetermined number of the pulses from the pulse shaper 56, then resets. For example, if the generator 50 produces 60 cycles per second, the counter 58 might count 12 pulses, then reset, to provide a reset rate of 5 per second. A decoder 60 produces a logic level on outputs 62, 63 and 64 in response to three different counts on the counter 58. For example, the decoder 60 might produce a logic 1 level on output 62 when the counter reaches the count of one, a logic I level on output 63 when the counter reaches five, and'a logic 1 level on output 64 when the counter reaches nine.

lnverter 66 applies the complement of the pulse shaper 56 to each of the AND gates 68, 69 and 70. As a result, AND gate 68 produces an output pulse at the beginning of the negative half cycle from the generator 50 which follows the positive pulse that reset the counter 58 to the count of one. AND gate 69 produces an output at the start of the negative going cycle following the pulse which caused the counter 58 to increment to the count of five, and AND gate 70 produces an output at the start of the negative half cycle after the ulse that incremented the counter 58 to a count of nine.

One output from the generator 50 is connected to ground, and the other is connected by way of ON-OFF switches 72, 73 and 74 to trigger circuits 75, 76 and 77. The triggr circuits 76 and 77 are identical to the trigger circuit 75, and accordingly, only trigger circuit 75 will now be described in detail. The power from generator 50 is connected through switch 72 to an auto transformer 78. The output from the auto transformer 78 is connected through a rectifying means comprised of a pair of diodes 80 to the output of the trigger circuit. A gate controlled rectifier 90, such as a silicon controlled rectifier (SCR), and a current limiting resistor 92 are connected parallel to the diode 80. The output pulse from AND gate 68 passes through the primary winding 94 of a transformer and then to ground. This pulse induces a current in the secondary winding 96 which is connected to the gate of the SCR 90 and turns the SCR on. Diode 98 and resistor 100 are provided to protect the SCR in the conventional manner. An insulated conductor 82 from tensioning spool 84 is connected to the output of the trigger circuit and to an input terminal 86 of the pulse circuit 88 which is disposed within the watertight container 36 mounted on the door 20 of the trawl 12. The input terminal 86 is connected through the primary winding 102 of a transformer to a first plate ofa large capacitor 104. The second plate of the capacitor is connected to an output terminal 106 of the pulse circuit. The first plate of the capacitor 104 is also connected by an SCR 108 to a second output terminal 110. The SCR 108 is turned on only by current induced in the secondary winding 112 of the transformer as a result of current discharged from the capacitor 104 through the primary winding 102. A diode 114 and resistor 116 protect the SCR 108 in the conventional manner.

The output 110 of the pulse generator is connected to electrodes 40a of the array, and the other output 106 is connected to the alternateelectrodes 40b. Output 106 is also connected to the two cable 30 which is connected through the winch 118 on the boat 10 to ground.

The output from the trigger circuit 76 is similarly connected through an insulated conductor 120 from a tensioning spool 122 to the input of a pulse generator 124, which is located on the trawl 14. The output from the pulse generator 124 is connected to the electrode array 126 of the trawl 14 and to the cable 128 from the winch 130 used to tow the trawl 14. The output from the trigger 77 is connected to tensioning spool 131 to insulated cable 132 and then to the pulse generator 134, which is located on the try net 16. The outputs from the pulse generator 134 are connected to an electrode array 136 of the try net and to the two cable 138 which is grounded through the winch 140.

The operation of the system of FIG. may best be understood by reference to the timing diagram of FIG.

6. Assuming that the switches 72, 73 and 74 and closed so that all nets are in operation, the capacitor 104 of each of the pulse generators would be charged by current through the diodes 80 so that the plate connected 1 to the primary winding 102 is positive with respect to output 106, which is grounded. This charge is held by diodes 80 because SCRs 90 and 108 are turned off. The charge on the capacitor 104 is represented by curve 88a.

Assume that the output from the generator 50 is represented by wave form 50a. The output from the pulse shaper 56 might then appear as the wave form 56a. The counter 58 increments to the counts designated 1-12 in connection with the wave form 5611. If the decoder 60 produces a logic 1 level on outputs 62, 63 and 64 on the counts of one, five, and nine, respectively, then the output from gates 68, 69 and would be indicated by wave forms 68a, 69a and 70a. As the output from AND gate 68 rises, the current induced in secondary winding 96 turns SCR 90 on which starts to discharge capacitor 104 through the primary winding 102. This immediately induces sufficient current in the secondary winding 112 to turn SCR 108 on, which immediately discharges capacitor 104 across the adjacent electrodes 40a and 40b of the array 37 connected to the outputs 106 and 110. This current pulse is represented by the wave form 37a in FIG. 6.

It is important to note that this occurs at the beginning of a negative half-cycle from the generator 50. As the SCR 90 continues to conduct during the negative half-cycle, the charge on the capacitor 104 goes negative, thus reverse biasing SCR 108 to insure a sharp cutoff. Then as the output of the generator 50 again goes positive, SCR 90 is reversed bias to cutoff as a result of the voltage drop across diodes 80, thus again setting up the condition which permits the capacitor 104 to be charged.

The current output from the trigger circuit is indicated by wave form 75a. It will be noted that during the initial charging cycle of the capacitor 104, the current to the capacitor is relatively large, but decreases exponentially as the charge on the capacitor is increased. The load on the generator 50 is materially reduced by the time the counter 58 has reached the count of five so that an output is produced from gate 69 to actuate trigger circuit 76. The pulse from gate 69 is represented by wave form 690. This results in a current pulse being delivered to electrode array 126, as represented by wave form 126a by the discharge of the capacitor 104 of the pulse generator 124, the voltage of which is represented by the wave form 124a, and the subsequent drawing of current from the trigger circuit 76 as represented by wave form 76a to recharge the pulse generator 124. The AND gate 70 produces an output following a count of nine, as represented by wave form 70a, the load on the generator 50 has been reduced as represented by wave form 76a. The pulse 70a results in a current pulse represented by wave form 136a, being delivered to the electrode array 136 with the attendant decrease in the charge on the capacitor of the pulse generator 134, as represented by wave form 134a, and a subsequent current drain through the trigger circuit 77, as represented by wave form 77a. Thus it will be noted that the load on the generator 50 is substantially equalized.

Assuming that the generator 50 produces 60 cycle power, each of the electrode arrays will produce pulses at a rate of five per second. Of course, other pulse rates can be produced by either changing the length of'the reset cycle of counter 58, by changing the pulse rate produced by pulse shaper 56. i

Referring now to FIG. 7, the bus 38 is comprised of a pair of conductors 38a and 38b which are connected to outputs 110 and 106, respectively. Electrodes 40a are connected to conductor 38a. It will be noted that the conductor 38b extends across the array and returns from the opposite side before being connected to the electrodes 40b. This insures that the voltage between each adjacent pair of electrodes 40a and 40b is constant over the entire array and is not distorted by IR drops across the array.

An alternative configuration is illustrated in FIG. 8 wherein two pulse generators 36a and 36b, identical to the pulse generator 36, are mounted on the trawl doors and 18, respectively. In this case, both of the pulse circuits 36a and 36b are charged and discharged through the same insulated conductor 82, and the ground returns are connected to bridle cables 26 and 28, and thus by cable 30.

Each of the electrodes a and 40b are preferably constructed as illustrated in FIG. 9, although it is to be understood that other types of electrodes can be used with the system of the present invention. The electrode 40a, for example, is comprised of a strip of flat plastic material 200 which is mechanically connected to the bus wires 38 for support. A flat braided metal electrode 202 is connected to the lower surface of the insulating material 200 along a substantial portion of its length. This metal electrode 202 is electrically connected by a wire 204 to the bus wire 38a. A weight 206 is attached to the lower face of the plastic strip 200 at point spaced from the bus wires 38, and a similar weight 208 is attached at the rear end so that the electrode 202 will be disposed in a generally horizontal position adjacent the bottom as the trawl is towed through the water.

The electrode construction illustrated in FIGS. 9 and 10 increases the resistance above the electrodes so that more'current is directed into the bottom, thus increasing the voltage applied to the shrimp. If desired, the braided electrodes may be passed through the plastic strip to the top side for short intervals to direct the electric current upwardly, and thus continue to stimulate the shrimp above the plane of the electrodes from time to time. i

Since the bus cables 38 are disposed a substantial distance above the bottom of the trawl doors, the cables will pass over rocks, seaweed and other obstacles. The length of the plastic strip between the bus wires 38 and the forward weight 206 is preferably sufficient for the electrodes to sink substantially below the plane of the footrope and the bottom of the trawl doors, and thus enable the electrodes to penetrate seaweed and the like to a position adjacent the bottom.

Another electrode array in accordance with the present invention is indicated generally by the reference numerals 220 in FIG. 11. FIG. 11 is a bottom view of three electrodes of the array which are designated 222a and 222b. Each electrode may be a conventional braided or twisted cable with insulation 224. The electrodes 222a and 222b are connected to the positive and negative wires 38a and 38b, respectively. The electrode 6 wire'in areas 224a 224b, respectively. The areas 224a are staggered in relation to the areas 224b so that current flows in lines extending diagonally of the direction of travel of the array. As a result of this-arrangement, the current is again directed downwardly into the mud, but in a crossed rather than a parallel pattern. As a result, a shrimp burrowed in the bottom will be subjected to currentfrom two different directions as the array passes. This substantially reduces the possibility that a shrimp will be lying at to the current flow, and thus will not be stimulated by a sufficient voltage from head to tail to cause the involuntary contraction necessary to deburrow the animal.

Although preferred embodiments of the invention have been described, it is to be understood various changes, substitutions and alterations can be made therein without departing from the spirit of the scope of the invention as defined by the appended claims.

What is claimed is:

1. The electrical trawling system which comprises:

a boat;

an alternating current generator carried by the boat;

a plurality of trawl nets each pulled by a tow cable from the boat, each trawl net having an electrode array including at least two electrodes;

a pulse circuit connected to each trawl net having a capacitor and circuit means for charging the capacitor and for selectively discharging the capacitor across said at least two electrodes when triggered from the boat; and

control circuit means on the boat electrically connecting the generator to each of the pulse circuits for charging the capacitors of the respective pulse circuits and for triggering the respective pulse circuits in a predetermined sequence to average the load on the generator.

2. The system of claim 1 wherein each pulse circuit comprises:

a first terminal;

a capacitor connected between the first terminal and one of the electrodes for storing a charge as a result of current of one polarity applied at the first terminal;

a gate controlled rectifierconnecting the capacitor to. the other electrode for discharging the charge stored on the capacitor across the electrodes when turned on; and

gate circuit means responsive to current of the other polarity from the capacitor to the output terminal for turning the gate controlled rectifier on before the capacitor has discharged whereby the charge on the capacitor will be largely dissipated through the gate controlled rectifier means andacross the electrodes;

3. The system of claim 2 wherein the gate circuit means is inductively coupled to the circuit between the capacitor and the input terminaL.

4. The system of claim 2 wherein the control circuit means includes:

rectifier means connecting the generator to the first terminals of the respective pulse circuits for charging the capacitor with current of said one polarity, and

switching means for selectively discharging, in the predetermined sequence, the respective capacitors by bypassing the rectifier means to produce the current of said other polarity and thereby trigger the gate controlled rectifier means of the respective pulse generator on.

5. The system of claim 4 wherein the switching means starts the discharge of the respective capacitors during the portion of the generator cycle when no current is being supplied to charge the capacitors.

6. The system of claim 4 wherein the switching means connects the input terminals of the respective pulse generator means to the generator during the portion of the generator cycle that has an opposite potential to the charge on the respective capacitors whereby the respective gate controlled rectifier device will be back biased and turned off after the respective capacitor has been discharged.

7. The system of claim 2 wherein the input terminal of each pulse circuit is connected to the generator by an insulated electrical conductor extending from the boat to the pulse circuit and said one electrode is electrically connected to the tow cable which is an electrical conductor and is grounded to the boat and water.

8. The system of claim 1 wherein the control circuit means comprises:

a counter for counting the cycles of the generator through a reset cycle having a reset rate of from about 3 cycles to about 7 cycles per second,

decoder means for detecting a different count of the counter during each reset cycle for each pulse circuit, and

means for triggering the respective pulse circuits upon the detection of the respective different counts. 1

9. The electric trawling system which comprises:

a boat;

a source of electrical power carried by the boat;

a trawl net pulled by a tow cable from the boat including an electrode array having at least one electrode,

a pulse circuit connected to the trawl net having a capacitor and circuit means for charging the capacitor and for discharging the capacitor to the electrode when triggeredfrom the boat, and

control circuit means on the boat electrically connecting the source of electrical power to the pulse circuit for charging the capacitor and for triggering the pulse circuit at a rate controlled from the boat. 10. In an electric fishing apparatus, the combination a source of electrical power,

a trawl net,

an electrically conductive non insulated tow cable for pulling the trawl net through the water, the tow cable being electrically connected to one terminal of the source of electrical power,

at least two electrodes associated with the trawl net, one of the electrodes being electrically connected to the tow cable,

a pulse generator associated with the trawl net and connected to supply electrical pulses to another of the electrodes, and

a single insulated electrical conductor electrically connecting the other terminal of the source of electrical power to the pulse generator.

11. A trawl net comprising,

a pair of Otter doors, v

a trawl connected to the Otter doors by a headrope and a footrope,

a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors, and

a plurality of electrodes connected at one end to the bus wire with the other ends trailing free, at least a portion of the electrodes comprising an elongated electrical conductor with an insulating strip wider than the conductor disposed above the conductor.

12. The trawl net of claim 11 wherein the electrical conductor is a flat cable comprised of a plurality of individual wires connected to a flat insulating strip.

13. A trawl net comprising:

a pair of Otter doors,

a trawl connected to the Otter doors by a headrope and a footrope,

a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors, and

a plurality of electrical conductors connected at one end to the bus wire with the other ends trailing free, the conductors being partially insulated such as to leave electrodes exposed to the water only at staggered intervals whereby a potential applied to adjacent conductors will result in current flowing diagonally of the conductors.

14. In a fishing apparatus having a pair of Otter doors and a trawl net connected to the Otter doors by a headrope and a footrope, the improvement comprising:

an electric pulse generator mounted on one Otter door having a pair of output terminals,

a first wire connected to one of the terminals and extending toward the other Otter door,

a second wire connected to the other terminal having a first reach extending substantially to the other Otter door and a second reach returning at least a portion of the way, the first reach being substantially electrically insulated, and

electrode means connected to the first wire and to the second reach of the second wire for producing an electrical field in the water adjacent the trawl.

l5. ln-an electrical fishing apparatus, the improvement comprisingat least two electrodes extending in generally parallel relationship and insulation means on at least a portion of the electrodes substantially reducing the exposed surface area of the electrode over a substantial length of the portion of the electrode which dissipates current into the water for controlling the electric field produced in the water by a potential applied to the electrodes.

16. The improvement of claim 15 wherein the electrodes are exposed to the water only at staggered intervals to produce an electric field that is polarized diagonally of the electrodes.

17. An electrical fishing apparatus comprising:

a pair of Otter doors,

a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors,

a plurality of electrodes connected at one end to the bus wire with the other ends trailing free,

a source .of electrical pulses connected to one of the Otter doors and having a pair of electrical output terminals,

one of the conductors of the bus being connected to one of the output terminals and extending from the source toward the other door,

the other of the conductors of the bus being connected to the other of the output terminals and extending from the source toward the other door and returning, and

one group of the electrodes being electrically connected to said one conductor and another group of the electrodes being electrically connected to the return of the other conductor.

18. An electrical fishing apparatus comprising:

a pair of Otter doors,

a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors,

a plurality of electrodes connected at one end to the bus wire with the other ends trailing free,

a source of electrical pulses connected to each of the Otter doors, each source having a pair of electrical output terminals,

each conductor of the bus being electrically connected to one terminal of each source, and

one group of the electrodes being electrically connected to one of the conductors and another group of the electrodes being electrically connected to the other conductor. 19. The electric fishing apparatus comprising the combination of:

an electrical conductor, an electrical insulator disposed on one side of the conductor for increasing the current flowing away from the insulator, and means for maintaining the insulator in a predetermined relationship to the conductor as the two are moved through water directing the current in a predetermined manner. 20. The combination of claim 19 wherein the insulator is maintained above the conductor as the two are moved through the water near the bottom for increasing the current directed into the bottom. 21. The combination of claim 19 wherein the con ductor is a flat cable of braided wires and the cable is fixed to one surface of a flat strip of insulating material. 

1. The electrical trawling system which comprises: a boat; an alternating current generator carried by the boat; a plurality of trawl nets each pulled by a tow cable from the boat, each trawl net having an electrode array including at least two electrodes; a pulse circuit connected to each trawl net having a capacitor and circuit means for charging the capacitor and for selectively discharging the capacitor across said at least two electrodes when triggered from the boat; and control circuit means on the boat electrically connecting the generator to each of the pulse circuits for charging the capacitors of the respective pulse circuits and for triggering the respective pulse circuits in a predetermined sequence to average the load on the generator.
 2. The system of claim 1 wherein each pulse circuit comprises: a first terminal; a capacitor connected between the first terminal and one of the electrodes for storing a charge as a result of current of one polarity applied at the first terminal; a gate controlled rectifier connecting the capacitor to the other electrode for discharging the charge stored on the capacitor across the electrodes when turned on; and gate circuit means responsive to current of the other polarity from the capacitor to the output terminal for turning the gate controlled rectifier on before the capacitor has discharged whereby the charge on the capacitor will be largely dissipated through the gate controlled rectifier means and across the electrodes.
 3. The system of claim 2 wherein the gate circuit means is inductively coupled to the circuit between the capacitor and the input terminal.
 4. The system of claim 2 wherein the control circuit means includes: rectifier means connecting the generator to the first terminals of the respective pulse circuits for charging the capacitor with current of said one polarity, and switching means for selectively discharging, in the predetermined sequence, the respective capacitors by bypassing the rectifier means to produce the current of said other polarity and thereby trigger the gate controlled rectifier means of the respective pulse generator on.
 5. The system of claim 4 wherein the switching means starts the discharge of the respective capacitors during the portion of the generator cycle when no current is being supplied to charge the capacitors.
 6. The system of claim 4 wherein the switching means connects the input terminals of the respective pulse generator means to the generator during the portion of the generator cycle that has an opposite potential to the charge on the respective capacitors whereby the respective gate controlled rectifier device will be back biased and turned off after the respective capacitor has been discharged.
 7. The system of claim 2 wherein the input terminal of each pulse circuit is connected to the generator by an insulated electrical conductor extending from the boat to the pulse circuit and said one electrode is electrically connected to the tow cable which is an electrical conductor and is grounded to the boat and water.
 8. The system of claim 1 wherein the control circuit means comprises: a counter for counting the cycles of the generator through a reset cycle having a reset rate of from about 3 cycles to about 7 cycles per second, decoder means for detecting a different count of the counter during each reset cycle for each pulse circuit, and means for triggering the respective pulse circuits upon the detection of the respective different counts.
 9. The electric trawling system which comprises: a boat; a source of electrical power carried by the boat; a trawl net pulled by a tow cable from the boat including an electrode array having aT least one electrode, a pulse circuit connected to the trawl net having a capacitor and circuit means for charging the capacitor and for discharging the capacitor to the electrode when triggered from the boat, and control circuit means on the boat electrically connecting the source of electrical power to the pulse circuit for charging the capacitor and for triggering the pulse circuit at a rate controlled from the boat.
 10. In an electric fishing apparatus, the combination of: a source of electrical power, a trawl net, an electrically conductive noninsulated tow cable for pulling the trawl net through the water, the tow cable being electrically connected to one terminal of the source of electrical power, at least two electrodes associated with the trawl net, one of the electrodes being electrically connected to the tow cable, a pulse generator associated with the trawl net and connected to supply electrical pulses to another of the electrodes, and a single insulated electrical conductor electrically connecting the other terminal of the source of electrical power to the pulse generator.
 11. A trawl net comprising, a pair of Otter doors, a trawl connected to the Otter doors by a headrope and a footrope, a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors, and a plurality of electrodes connected at one end to the bus wire with the other ends trailing free, at least a portion of the electrodes comprising an elongated electrical conductor with an insulating strip wider than the conductor disposed above the conductor.
 12. The trawl net of claim 11 wherein the electrical conductor is a flat cable comprised of a plurality of individual wires connected to a flat insulating strip.
 13. A trawl net comprising: a pair of Otter doors, a trawl connected to the Otter doors by a headrope and a footrope, a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors, and a plurality of electrical conductors connected at one end to the bus wire with the other ends trailing free, the conductors being partially insulated such as to leave electrodes exposed to the water only at staggered intervals whereby a potential applied to adjacent conductors will result in current flowing diagonally of the conductors.
 14. In a fishing apparatus having a pair of Otter doors and a trawl net connected to the Otter doors by a headrope and a footrope, the improvement comprising: an electric pulse generator mounted on one Otter door having a pair of output terminals, a first wire connected to one of the terminals and extending toward the other Otter door, a second wire connected to the other terminal having a first reach extending substantially to the other Otter door and a second reach returning at least a portion of the way, the first reach being substantially electrically insulated, and electrode means connected to the first wire and to the second reach of the second wire for producing an electrical field in the water adjacent the trawl.
 15. In an electrical fishing apparatus, the improvement comprising at least two electrodes extending in generally parallel relationship and insulation means on at least a portion of the electrodes substantially reducing the exposed surface area of the electrode over a substantial length of the portion of the electrode which dissipates current into the water for controlling the electric field produced in the water by a potential applied to the electrodes.
 16. The improvement of claim 15 wherein the electrodes are exposed to the water only at staggered intervals to produce an electric field that is polarized diagonally of the electrodes.
 17. An electrical fishing apparatus comprising: a pair of Otter doors, a bus wire connected to the Otter doors and extending therebetween having at least two electrIcal conductors, a plurality of electrodes connected at one end to the bus wire with the other ends trailing free, a source of electrical pulses connected to one of the Otter doors and having a pair of electrical output terminals, one of the conductors of the bus being connected to one of the output terminals and extending from the source toward the other door, the other of the conductors of the bus being connected to the other of the output terminals and extending from the source toward the other door and returning, and one group of the electrodes being electrically connected to said one conductor and another group of the electrodes being electrically connected to the return of the other conductor.
 18. An electrical fishing apparatus comprising: a pair of Otter doors, a bus wire connected to the Otter doors and extending therebetween having at least two electrical conductors, a plurality of electrodes connected at one end to the bus wire with the other ends trailing free, a source of electrical pulses connected to each of the Otter doors, each source having a pair of electrical output terminals, each conductor of the bus being electrically connected to one terminal of each source, and one group of the electrodes being electrically connected to one of the conductors and another group of the electrodes being electrically connected to the other conductor.
 19. The electric fishing apparatus comprising the combination of: an electrical conductor, an electrical insulator disposed on one side of the conductor for increasing the current flowing away from the insulator, and means for maintaining the insulator in a predetermined relationship to the conductor as the two are moved through water directing the current in a predetermined manner.
 20. The combination of claim 19 wherein the insulator is maintained above the conductor as the two are moved through the water near the bottom for increasing the current directed into the bottom.
 21. The combination of claim 19 wherein the conductor is a flat cable of braided wires and the cable is fixed to one surface of a flat strip of insulating material. 